Affinity protocols for the purification of urinary trypsin inhibitor (UTI) were developed. To imitate the substrate/inhibitor-binding domain (S1 domain) of trypsin and chymotrypsin, the key amino acid residues were composed to sorbents. The sorbents were then subjected to adsorption analysis with UTI. The purification process consisted of one step of affinity chromatography and another step of ultrafiltration. The purified enzyme was subjected to SDS-PAGE, trypsin inhibitor activity and peptide map fingerprinting analysis. As calculated, the theoretical maximum adsorption (Q(max)) of two affinity sorbents entitled as S-D-G and S-S-G were 31.7 and 30.1 mg/g, respectively; the desorption constants K(d) of the two sorbents were 8.9 and 18.6 μg/mL, respectively. After the separation of UTI with S-D-G and S-S-G, reducing SDS-PAGE analysis revealed that the protein was a single polypeptide with the mass of ~66 kDa, and the purified proteins were ~95 and 97% pure, respectively; the band on gel was further confirmed with peptide map fingerprinting analysis. Protein and bioactivity recoveries were 1.3 and 75.9% with S-D-G, 1.0 and 70.2% with S-S-G, respectively.
Affinity ligands for flavoenzymes were synthesized based on the natural structure of flavo-coenzymes. Two typical flavoenzymes, cholesterol oxidase from Brevibacterium sp. and xanthine oxidase from bovine milk, were employed as standard enzymes. Fluorescent probes were synthesized from eight isoalloxazine-like chemicals and 5-aminofluorescein. Probe-enzyme interactions were analyzed via fluorescence spectra. Chemicals with high binding abilities to flavoenzymes were coupled with Sepharose through spacers composed of epichlorohydrin, ethylenediamine, 1,3-diaminopropane, 2-hydroxy-1,3-diaminopropane, and 1,4-diaminobutane, and subjected to adsorption analysis with flavoenzymes. The results indicated that ligands synthesized from 2,4-dioxohexahydropyrimidine-5-carboxylic acid, cytosine, 7-chloroalloxazine, and 8-chloroalloxazine had high binding abilities to the flavoenzymes. The affinity sorbent based on these ligands revealed a high theoretical maximum adsorption (Q(max)). Protein and bioactivity recoveries were tested after one step of affinity binding via chromatographic analysis on small columns. Results showed that ligands linked with sorbents through long hydrophilic spacers had higher activity recoveries.
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